HYDROLOGICAL PROPERTIES OF AGRICULTURAL SOIL UNDER TREATMENT WITH DIFFERENT LEVELS OF BIOCHAR-BASED NANOPARTICLE

Authors

  • O. G. Dayo-Olagbende Department of Agricultural Sciences, Afe Babalola University Ado-Ekiti, Nigeria
  • D. O. Babadele Department of Crop, Soil and Pest Management, Olusegun Agagu University of Science and Technology, Okitipupa, Ondo State, Nigeria
  • K. O. Sanni Department of Crop Science, Lagos State University of Science and Technology, Ikorodu, Lagos State, Nigeria
  • K. M. Adetimehin Department of Crop, Soil and Pest Management, The Federal University of Technology, Akure, Ondo State, Nigeria
  • B. S. Ewulo Department of Crop, Soil and Pest Management, The Federal University of Technology, Akure, Ondo State, Nigeria

DOI:

https://doi.org/10.4314/njt.v43i4.19

Keywords:

biochar, nanoparticles, clay flocculation, void ratio, dispersion ratio

Abstract

Soil hydrology plays a crucial role in many fields of study, including agriculture, due to the variation in the length of the rainy season brought about by erratic weather patterns. To mitigate crop failure, sustainable and drought-resistant agricultural techniques must be developed. This can be achieved by comprehending the transformative effects of nanoparticles on soil structure, water availability, and nutrient dynamics. Hence, this study aims to explore the impact of biochar-based nanoparticles on the hydrological properties of agricultural soil. Six (6) levels of biochar-based nanoparticles were used as treatments at 0 g, 100 g, 200 g, 300 g, 400 g, and 0 g with constant water supply as control applied to 20 g of soil. The hydrological properties considered are clay flocculation, dispersion ratio, structural stability, void ratio, sodium percentage, and water retention ability, among others, are relevant to agriculture. Biochar addition initially increased soil moisture retention and soil aggregation, but impaired stability at excessive levels due to nanoparticle toxicity. Clay flocculation dramatically improved with 100 g of biochar nanoparticle, yet severely declined beyond 200 g due to toxicity inhibiting natural aggregation. Lower biochar application rates increased aggregate stability compared to control samples, but stability did not increase proportionately as biochar application increased. Compared to higher amounts, the void ratio significantly changed with 100 g biochar addition, .patterns in stability and sodium content indicate biochar nanoparticles profoundly altered soil structure, highlighting the narrow threshold between benefits and ecosystem damage from excessive application. It was concluded that as much as biochar-based nanoparticles can help improve the hydrological properties of the agricultural soil, application beyond 200 g could have a counter effect and hence has to be monitored.

References

[1] Ayanlade, A., Radeny, M. and Morton, J.F. “Rainfall variability influences on maize production in Nigeria: insights from arima models”, Peer J, 6, 2018; p.e5249. https://doi. org/10.7717/peerj.5249

[2] Chausali, D., Pal, M., Jha, C.K. and Patra, D.D. “Production and characterization of biochar nanoparticles from lignocellulosic biomass”, Nano-Structures & Nano-Objects, 26, 2021; p.100801. https://doi.org/10.1016/j.nanoso.202 1.100801

[3] Behnam, H., and Firouzi, A. F. “Effects of synthesis method, feedstock type, and pyrolysis temperature on physicochemical properties of biochar nanoparticles”,. Biomass Conversion and Biorefinery, 13(15), 2023; 13859-13869.

[4] Farah, F., Biswas, B. and Cheng, Y. “Biochar nanoparticles: Synthesis mechanisms, proper-ties, stability, and effects on biological processes in agricultural systems”, Advances in agronomy, 168, pp.1-61. https://doi.org/10.10 16/bs.agron.2021.11.001

[5] Behnam, S. and Firouzi, A. “Controlling biochar nano particle properties via feedstock characteristics and pyrolysis conditions. Journal of hazardous materials”, 430, 2022, p.128403. https://doi.org/10.1016/j.jhazmat.20 22.128403

[6] Yadav, M., Özyurt, D., Mueller, L., Singh, B.P., Rathore, P.S. and Saharan, V. “A Review on Nanoscale Zero-Valent Iron- and Magnetite Nanoparticle-Mediated Remediation of Organic Pollutants in Agricultural Soils. Nan-omaterials”, 13(1), 2023, p.193. https://doi.org/ 10.3390/nano13010193

[7] Zhang, S., Tian, G., Ao, Y., Li, S., Wang, S. and Bian, R. “Effect of biochar amendment on soil salinity and okra growth and its mechanisms in coastal saline zone”, Chemical Speciation & Bioavailability, pp.1-10. https://doi.org/10.10 80/09542299.2023.2111362

[8] Gao, B., Chen, S., Chen, X. and Creamer, A.E. “Organic compounds leach biochar nanoparticles from soil: Implication for their transport in saturated porous media”, Chemosphere, 287, 2022; p.132061. https://doi .org/10.1016/j.chemosphere.2021.132061

[9] Wang, X., Chen, L., Gu, X., Wei, H., Tang, Z., Huang, Z. and Chen, W. “Effect of biochar amendment on soil bacterial community composition and network interactions in the rhizosphere of cucumber under continuous cropping”, Applied Soil Ecology, 177, p.104402. https://doi.org/10.1016/j.apsoil.202 2.104402

[10] Tracy, P.W., Zhang, Y., Dufault, R.J., Sheaffer, C.C. and Mulvaney, M.J. “The effect of soil compaction and moisture on cotton and kenaf roots and subsequent plant growth”, The Journal of Cotton Science, 24(1), 2020; pp.50-58. https://citeweb.info/20200025637

[11] Shaikh, F.U.A., Shaikh, F.U.A., Memon, S.Q., Bhanger, M.I., El-Turki, A. and Hyder, S. “Adsorptive removal of toxic dyes using nano-adsorbents: A review”, Science of The Total Environment, 753, 2021, p.141942. https://doi. org/10.1016/j.scitotenv.2020.141942

[12] Uzoma, K.C., Chen, F., Melo, N., Zheng, J., Zhang, X., Cheng, K., Zhu, Z., Zhang, J., Wang, J., Guo, S., Liu, C., Cai, Q., Pan, G., Rehman, M.Z.U., Li, Q., Crowley, D., Zheng, J., Yu, X., Parikh, S.J. and Zhao, X. “Biochar technology in agriculture: Mechanisms, applicability, and challenges”, Nature Food, 3(1), 2022, 5-18. https://doi.org/10.1038/s43 016-021-00413-x

[13] Peng, X., Zhong, Z., Ren, J., Sun, L., Zhang, N., Guo, S. and Sun, H. “Role of biochar porous structure in adsorption of metal (loid) s: A review”, Chemosphere, 262, 128334. https://d oi.org/10.1016/j.chemosphere.2020.128334

[14] Ouyang, L., Wang, F., Tang, J., Yu, L., and Zhang, R. “Effects of biochar amendment on soil aggregates and hydraulic properties”, Journal of Soil Science and Plant Nutrition, 13(4), 2013, 991-1002. https://doi.org/10.406 7/S0718-95162013005000078

[15] Joseph, S., Graber, E. R., Chia, C., Munroe, P., Donne, S., Thomas, T., Nelson, Y. M., O'Halloran, I. P., He, Y., Zhang, J., Hao, X., Shinogi, Y., and Li, L. “Shifting paradigms: Development of high-efficiency biochar fertilizers based on nano-structures and soluble components”, Carbon Management, 4(3), 2013, 323-343. https://doi.org/10.4155/cmt.13 .23

[16] Anderson, S. H., Peyton, R. L., and Gantzer, C. J. “Evaluation of constructed and natural soil macropores using X‐ray computed tomography”, Geoderma, 160(3-4), 2011, 533-542. https://doi.org/10.1016/j.geoderma.2010. 11.013

[17] Clay, S. A., Clay, D. E., Koskinen, W. C., and Malo, D. D. “The sorption and leaching potential of biochar”, In Biochar Application, 2022, pp. 1-24. Elsevier. https://doi.org/10. 1016/B978-0-12-818578-7.00001-5

[18] Gong, B., Zhang, N., Wang, D., Cheng, M., Wang, X., and Wei, Q. “Effects of biochar application on microbial activity and community composition in vineyard soil under different soil water conditions”, Science of the Total Environment, 636, 2018, 760-767. https://doi.org/10.1016/j.scitotenv.2018.04.277

[19] Qian, L. and Chen, B. “Interactions of aluminum with biochars and oxidized biochars: implications for the biochar aging process”, Journal of agricultural and food chemistry, 62(2), 2014, 373–380. https://doi.org/10.102 1/jf404624h

[20] Qadir, M., Ghafoor, A., and Murtaza, G. “Use of saline-sodic waters through phytoreme-diation of calcareous saline-sodic soils”, Agricultural Water Management, 50(3), 2001, 197-210. https://doi.org/10.1016/S0378-3774( 01)00104-5

[21] Masud, M. M., Al-Amin, A. Q., Janaiah, A., Patra, A. K., and Purakayastha, T. J. “Effects of biochar, cowdung and poultry litter on maize growth and properties of soils with different textures”, Geoderma, 234, 2014, 209-217. https://doi.org/10.1016/j.geoderma.2014.07.016

[22] Suliman, W., Harsh, J. B., Abu-Lail, N. I., Fortuna, A. M., Dallmeyer, I., and Garcia-Pérez, M. “The role of biochar porosity and surface functionality in augmenting hydrologic properties of a sandy soil”, Science of the Total Environment, 574, 2017, 139-147.

[23] Razzaghi, F., Obour, P. B., and Arthur, E. “Does biochar improve soil water retention? A systematic review and meta analysis”, Geoderma, 361, 2020, 114055.

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Published

2025-01-08

Issue

Section

Agricultural, Bioresources, Biomedical, Food, Environmental & Water Resources Engineering

How to Cite

HYDROLOGICAL PROPERTIES OF AGRICULTURAL SOIL UNDER TREATMENT WITH DIFFERENT LEVELS OF BIOCHAR-BASED NANOPARTICLE. (2025). Nigerian Journal of Technology, 43(4), 788 – 794. https://doi.org/10.4314/njt.v43i4.19